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Stereochemistry Definition of Isomers If two or more different compounds have the same molecular formula we call them isomers. This is the general definition of isomer. There are two major classes (types) of isomers, and under these major classes there are further classifications of isomers as in Fig 1.
Now let us look individually at the different types of isomer and see some examples for each type.
Isomers
Constitutional or Structral Ismoers
Stereoisomer
EnantiomersDiastereomers
Geometric Isomers cis & trans
Conformational Isomers
Spatial Isomers
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Constitutional Isomers (structural isomers) Different compounds have the same molecular formula are called isomers and because they have different connectivity (which atom is bonded to which) we call them constitutional isomer or structural isomers.
Example 1
This compound has a molecular formula of C2H6O. Now we can draw two structures 1 & 2 for this molecular formula
Dimethyl ether 1 and Methanol 2 are constitutional isomers (or structural isomers) that because both of them have the same molecular formula C2H6O but they have different structures due to the differing in the bond connectivity of atoms to each other. In 1 the bonds are C-O-C and each C atom has 3 H atoms. In structure 2 the bonds are C-C-O and each carbon has 2H and there is a one H bonded to O atom. Example 2 The molecular formula of butane is C4H10. How many structure we can draw for butane in order to obtain a saturated hydrocarbon with molecular formula C4H10? There are only two different structures you can draw for C4H10 which are:
C2H6O
C
H
H
H O C
H
H
Dimethylether
H
C
H
H
H C
H
H
OH
Methanol
1 2
H C
H
H
C
H
H
C
H
H
n-Butane
CH
H
H C
H
CH
H
HH C
H
H
C HHH
isoButane
C4H10
3 4
3
Again The two structures have the same molecular formula but they have different connectivity (which atom is bonded to which) so they are constitutional isomers. Please note that 1 & 2 are completely two different compounds, they have different physical (b.p, mp, .etc.) and chemical properties. For example 2 is chemically active and it can reacts with carboxylic acid to form ester while 1 will not react. Now if I gave you modules for both 1 & 2, and ask you to convert 1 to 2 or vies versa You will never be able to do so without breaking the bonds and then re-build the molecules. The same thing is applicable in the case of structures 3& 4. We will never be able to interconvert from one structural isomer to another by rotation about bonds. We only can do that via only breaking bonds.
Which type of isomers that can interconvert to another isomer via rotation about bonds? If you do not know the answer, please go back to page 20 in the previous lecture notes and you will be able to answer this simple question.
In summary
Constitutional Isomers have the same molecular formula but have different bonds connectivity
Is that clear? If yes go to the next section if not try to revise the subject again and Please do not hesitate to ask me if you have any question
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2) Stereoisomers (spatial isomers) Stereoisomers (spatial isomers) different compounds that have the same molecular formula and the same bonds connectivity BUT they have different arranging (orientation) in the space (in 3D). There are two types of stereoisomers which are:
1) Conformational isomers 2) Configuratinal isomers
Both types are stereoisomers that mean both type have the same molecular formula and the same connectivity and both of them have different arrangement in the space!!! So what is the difference between them? In the Conformational isomers we can convert from one isomer to other isomers by just rotation about C-C bonds. We have seen examples on this type of isomers on page 21 in the hand out you have been given before. Any way; Ethane is good and simple example on conformational isomers. Let us look at the most two important
conformations of ethane staggered and eclipsed conformations.
Staggered conformation Eclipsed conformation Now apply the definition of stereoisomers on the two isomers and see what you will find out? The two structures have the same molecular formula that means they are isomers, they
have the same bond connectivity that mean they are stereoisomers, they have different bonds arrangement in the space and so they may be either conformational isomers or configuratinal isomers. For sure now we can say they are conformational isomers
C2H6Ethane
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because we can convert from staggered conformation to the eclipsed one via rotation about the C-C bonds.
Staggered conformation Eclipsed conformation
Another view
The conformations of propane, butane and all other conformations have the same property as the ethane so they all are conformational isomers.
In summery
Conformational isomers are stereoisomers that can be converted from one isomer to other isomers by rotation about C-C bond.
Is that clear? If yes go to the next section if not try to revise the subject again and Please do not hesitate to ask me if you have any question
H
H
HH
H
H
H
HH
HH
H
600 rotation about C-C
H
H H
H
HH
H
H H
H
HH
600 rotation about C-C
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Now let us look at the second type of stereoisomers; Configuratinal isomers. In the Configuratinal isomers we CAN NOT convert from one isomer to other isomers by rotation about bonds. We ONLY can convert from one isomer to other isomers via bond breaking.
There are two major types of Configuratinal isomers which are: 1) Geometrical isomers 2) Optical isomers
Geometrical isomers are isomers that have the same molecular formula, the same
bond connectivity but the atoms are in different non-equivalent positions to one another. Geometrical isomers occur as a result of restricted rotation about a carbon-carbon bond. Restricted rotation about C-C bond can arise in two different situations: (a) In a double bond (b) In a cyclic compound That mean geometrical isomers can arise only if we have a double bonds and/or cyclic structures.
Why there is no rotation about C=C and in the C-C in cyclic compound? First let us answer the first part of the question.
Well to answer this question we need to know what is the type of hybridization in the C=C. Let us look at the following example to understand the full story.
C4H8 is the molecular formula for the unsaturated hydrocarbon butene. We can draw butene in three different structures either as but-1-ene (1) or as but-2-ene (2) or as 2-methylpropene(3).
We will look only at the but-2-ene (2) as example of geometrical isomers. Can you tell what type of isomers is 1 & 2 & 3?
C4H8Butene
CH3CH=CHCH3CH2=CHCH2CH3but-1-ene but-2-ene
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2-methylpropene3
CH2=C-(CH3)2
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But-2-ene (2) can be drawn as the following two different structures 2-a and 2-b
CH3CH=CHCH3but-2-ene
2
2-a 2-b
(E)-but-2-ene (Z)-but-2-enecis-2-butenetrans-2-butene
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Optical Isomers In the previous sections we have seen that there are two types of configuratinal
isomers, and we have seen what geometrical isomers are. Now we will study the second type of configuratinal isomers which is the optical isomers. Optical isomerism is one form of stereoisomerism. In optical isomerism; the isomerism present at a tetrahedral center. We mean by tetrahedral center that a C atom attached to four other atoms or group with single bonds (sp3 hybridization).
Optical isomers are named like this because of their effect on plane polarised light (reacts with light) as we will see later. There are two major types of optical isomers 1) Enantiomers 2) Diastereomers However before we start studying the optical isomers in detals we need to learn some new scientific definitions related to the stereochemistry.
CHIRALITY (any thing can be chiral or Achiral) Chirality "handedness" (Greek cheir - the hand). Chiral objects (molecules) are these objects (molecules) which are not superimposable on (cannot be made to coincide with) their mirror image.
Superimposability The alignment of two images, one on top of the other.
HO
OH
Cl
tetrahedral center
tetrahedral center
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An object will exhibit handeness if it has no plane of symmetry. Plane of symmetry is a position where an object can be cut in half and each half is identical. In other words A plane of symmetry bisects a molecule into two mirror images halves
Chiral Carbon atom
The Chiral carbon is a carbon atom with 4 different atoms or groups attached directly to it. The hybridization on the chiral carbon must be sp3. Examples:
An sp3 hybridized carbon with 1, 2, or 3 different atoms or groups attached can be superimposed on its mirror image and is, therefore achiral. None of the following three compounds (a, b, c) is chiral because they do not have 4 different atoms or groups on the sp3 central C atom. Each of them are superimpose on its mirror image
Prochiral molecule: Is any molecule that can be converted to chiral molecule in a single step (one step chemical reaction). We will see examples at the end of the chapter.
X
CY
ZH
4-different atoms or groups attached to the C atom
CH2CH3C
CH3ClH
Cl
CF
BrH
* * *
a b c
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How you can draw chiral molecules?
EExxaammppllee::
DDrraaww tthhee ssttrruuccttuurree ooff 33--mmeetthhyyllhheexxaannee..
Now it is important to learn how to draw the mirror image of the structure. All what you need to do is to imagine that you have a mirro and draw what you will see
Example 2: 2-chlorobutane
CH3CH2CHCH2CH2CH3
CH3CH3CH2CHCH2CH2CH3
CH3*
CH2CH3
HCH2CH2CH3
H3C
C
bond away from you
bond closed to youbo
nds
onthe
plane
ofth
epa
per
draw the structure detect the chiral C draw one of the two stuctures
same
1 2 3
now attach the 4 groups to the chiral C
please note this
Cl
*
The star means there is chiral center on the C atom
The C holding the star has 4 different groups Me, Et, H, Cl Cl
CH3CH2 CH3H
Cl
CH2CH3H3CH
CH2CH3
C
H3CH2CH2C
CH2CH3
HCH2CH2CH3
H3C H CH3
mirror
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EEnnaannttiioommeerrss && CChhiirraalliittyy Molecules that are not superimposable on their mirror images are chiral. The existence of chirality is necessary and sufficient condition for the existence of enantiomers i.e. if a compound is chiral; it can exist as enantiomers and if it is Achiral it can not exist as enantiomers.
Enantiomers: Stereoisomers that are mirror image of each other and they are non-superimposable on their mirror images. In other words, if one isomer looked in a mirror, what it would see is the other one. The two isomers (the original one a and its mirror image b) have a different spatial arrangement, and so can't be superimposed on each other. All enantiomers are chiral (we will study them in more details soon)
Example:
In summery
Enantiomers: Stereoisomers that are mirror image of each other and they are non-
superimposable on their mirror images.
Cl
CH3CH2 CH3
H
Cl
CH2CH3H3C
H
(S)-2-chlorobutane (R)-2-chlorobutane
a b
mirror
Enantiomers
H
CI Cl
SO3H
H
CCl I
SO3H
mirror
H
CI Cl
SO3H
H
CCl I
SO3H
non superimposable enantiomers
H
CH3C CH3Cl
H
CH3C CH3Cl
mirror
H
CH3C CH3Cl
H
CH3C CH3Cl
superimposable not-enantiomers
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Properties of Enantiomers
Physical properties: Physical properties including melting point, boiling point, color, hardness, density, etc. All physical properties of pair of enantiomers are the same except for one propriety which is optical activity. (we will study it soon) Chemical properties: Enantiomers have identical properties, except toward chiral substances where they will behave differently. That mean a pair of enantiomers react in different way with external chirl molecule (we will study it later in this chapter)
Optical Activity
As we just mentioned all of the properties of the compounds that constitute a pair of enantiomers are identical. Boiling points, Melting points, solubility in typical organic solvents are all the same for both compounds of a pair of enantiomers, however the major difference between two enantiomers is how they interact with plane polarized light. Plane Polarized Light and Optical Activity
1) Light is composed of an oscillating electric and magnetic vector oriented at right angles to one another.
2) Under ordinary conditions, light rays emanating from a source have random orientations of their electromagnetic vectors.
3) If these vectors are forced into alignment in a single direction, the light is said to be plane polarized.
Plane polarized light light that has been passed through a nicol prism or other polarizing medium so that all of the vibrations are in the same plane.
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Polarimeter: an instrument used to measure optical activity (The amount of light rotation.
Diagram of a polarimeter
Optically active substance: A substance is optically active if it rotates the plane of polarized light. Now when a polarized light pass through a sample in the polarimeter there are two possibility:
1) The polarized light will pass straight without any reflection, that means either the substance in the polarimeter is not chiral (we do not care about that). OR
the substance in the polarimeter is an equal mixture of two enantiomers. In this cases we say the substance is optically inactive. Optically inactive substances are these substances which do not rotate the polarized light. An equal mixture of enantiomers is called Racemic mixture. Racemic mixture (or modification): a mixture containing equal quantities of enantiomers (50:50) that mean (chiral molecule and its mirror image). The racemic mixture is optically inactive because one molecule will rotate the
polarized light for example by 50 to the right, the other enantiomers will
rotate the polarized light by 50 to the left so they cancel each other (the resultant is zero).
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2) The second possibility when the polarized light of a polarimeter pass through a sample is the rotation of the polarized light either to the left or to the right depending on the nature of the substance. If such a rotation takes place we say the substance is optically active. For a substance to be optically active it must be chiral and it should be either single enantiomers or unequal mixture of enantiomers (one of them present in excess).
Dextrorotatory: when the plane of polarized light is rotated in a clockwise direction when viewed through a polarimeter (+)
Levorotatory: when the plane of polarized light is rotated in a counter-clockwise direction when viewed through a polarimeter (-)
The amount of rotation is called the observed optical rotation, , this value is obtained directly from the polarimeter and it depends on:
1. Concentration 2. length of the cell 3. the wavelength 4. solvent 5. temperature
To compare samples a quantity called the specific rotation, [] is measured Specific rotation: the angle of rotation of plane polarized light by a 1.00 gram per cm-3 sample in a 1 dm tube. [ ]D (D = sodium lamp, = 589 m). The following formula is used to calculate the specific rotation.
[]tC= /l x c
[]=specific rotation t=temperature in C =wavelength =observed rotation l= length of sample container in decimeters c=concentration in g/mL
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Configuration and the R & S Convention
The arrangement of four different groups or atoms attached to C atom i.e. chiral molecule is called configuration of the molecule. Two enantiomers i.e. chiral molecule and its mirror image have different configuration that mean they have different arrangement in space or in three dimensional (3D). This difference is very important as one enantiomer can be used as medicine while the other enantiomer may be poisoning. It is important to learn how to determine the configuration of enantiomers and now we will see how to do so.
Look at the following example: When you draw the strcture of 2-bromobutane you will find out that this is chiral molecule as it has a carbon attome with four different groups which are (H, Br, CH3 and CH3CH2). This mean that we can draw two structures, simply the compound and its mirror image i.e. the enantiomers of 2-bromobutane. Ofcourse they have the same melting point , boiling point, solubility and even the same name but we have learend that they are different compounds. Becuase they are different compounds we need to determine the configuration of each single isomer.
This part will be only described in the lectures and here I will only give the rules and example for practicing.
1. Cahn Ingold - Prelog sequence rules revisited a. Rule 1: Priority is established by the atomic numbers of the
attached atoms. An atom of higher atomic number takes precedence over
one of lower atomic number.
bromochloroiodomethane
4
2
1
31
2
3SBr
Cl I
Br
HICl
S-bromochloroiodomethane
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b. Rule 2: if two directly attached atoms have the same rank, rank the atoms along the substituent chain until a difference is found
c. Rule 3: Double and triple bonds are treated as if they were saturated connections
C CHH
RCC
H HR
CC
C C R C CC
C
C
CR
CO
R C RO
O
C
.
CH
HCH3 C
H
HH
higherpriority
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I
H ClBr
(R)-bromochloroiodomethane
OHH
(R)-butan-2-ol
HOH
(S)-butan-2-ol
HOH
(S)-butan-2-ol (R)-butan-2-ol
OHH
HOH
(S)-butan-2-ol
NH2
HO CH2OHH
(R)-1-aminoethane-1,2-diol
H
HO CH2OHNH2
(S)-1-aminoethane-1,2-diol
Cl
H3C H
CH2CH3
(S)-2-chlorobutane